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Researchers demonstrated controllable atomic-scale patterning and resistive switching in 2D cuprous telluride crystals. Their memristor model and applications in image processing signify progress towards advanced in-memory computing.
Researchers develop a simple technique for producing 3D porous fiber materials directly from solutions using a standard electrospinning setup, opening doors for customized insulation, absorbents, scaffolds, electrodes.
Researchers developed hypothermal opto-thermophoretic tweezers that use low laser power and cooling to precisely manipulate cells and nanoparticles without damage.
Scientists devise a novel strategy to completely maximize inexpensive MXene materials for scalable and reliable electronic fabrics with integrated capabilities.
Researchers develop a fully biodegradable and biocompatible ionotronic skin that rapidly dissolves in physiological fluids, opening the door to zero-waste wearable electronics.
Researchers use MXene to develop a flexible electronic skin that replicates the microstructures in human skin to achieve exceptional sensitivity. The multifunctional sensor also provides therapeutic heat treatment.
Researchers develop a new biomaterial fabrication technique combining co-extrusion and 3D printing to produce scaffolds with nanoscale layers, improving cardiomyocyte growth and function.
Researchers have developed sustainable hydrogels that capture carbon dioxide effectively from the air. These hydrogels work well in humid conditions and offer a low-energy, scalable solution for carbon capture technologies.